Phenotypical and structural characterization of the Arabidopsis mutant involved in shoot apical meristem

An Arabidopsis mutant induced by T-DNA insertion was studied with respect to its phenotype, micro-structure of shoot apical meristem (SAM) and histo-chemical localization of the GUS gene in comparison with the wild type. Phenotypical observation found that the mutant exhibited a dwarf phenotype with smaller organs (such as smaller leaves, shorter petioles), and slower development and flowering time compared to the wild type. Optical microscopic analysis of the mutant showed that it had a smaller and more flattened SAM, with reduced cell layers and a shortened distance between two leaf primordia compared with the wild type. In addi-tion, analysis of the histo-chemical localization of the GUS gene revealed that it was specifically expressed in the SAM and the vascular tissue of the mutant, which suggests that the gene trapped by T-DNA may function in the SAM, and T-DNA insertion could influence the functional activity of the related gene in the mutant, lead-ing to alterations in the SAM and a series of phenotypes in the mutant.     

The essential gene EMB1611 maintains shoot apical meristem function during Arabidopsis development

The Arabidopsis thaliana genome contains hundreds of genes essential for seed development. Because null mutations in these genes cause embryo lethality, their specific molecular and developmental functions are largely unknown. Here, we identify a role for EMB1611/MEE22 , an essential gene in Arabidopsis, in shoot apical meristem maintenance. EMB1611 encodes a large, novel protein with N-terminal coiled-coil regions and two putative transmembrane domains. We show that the partial loss-of-function emb1611-2 mutation causes a range of pleiotropic developmental phenotypes, most dramatically a progressive loss of shoot apical meristem function that causes premature meristem termination. emb1611-2 plants display disorganization of the shoot meristem cell layers early in development, and an associated stem cell fate change to an organogenic identity. Genetic and molecular analysis indicates that EMB1611 is required for maintenance of the CLV-WUS stem cell regulatory pathway in the shoot meristem, but also has WUS -independent activity. In addition, emb1611-2 plants have reduced shoot and root growth, and their rosette leaves form trichomes with extra branches, a defect we associate with an increase in endoreduplication. Our data indicate that EMB1611 functions to maintain cells, particularly those in the shoot meristem, roots and developing rosette leaves, in a proliferative or uncommitted state.     

Auxin-induced WUS expression is essential for embryonic stem cell renewal during somatic embryogenesis in Arabidopsis

Somatic embryogenesis requires auxin and establishment of the shoot apical meristem (SAM). WUSCHEL ( WUS ) is critical for stem cell fate determination in the SAM of higher plants. However, regulation of WUS expression by auxin during somatic embryogenesis is poorly understood. Here, we show that expression of several regulatory genes important in zygotic embryogenesis were up-regulated during somatic embryogenesis of Arabidopsis. Interestingly, WUS expression was induced within the embryonic callus at a time when somatic embryos could not be identified morphologically or molecularly. Correct WUS expression, regulated by a defined critical level of exogenous auxin, is essential for somatic embryo induction. Furthermore, it was found that auxin gradients were established in specific regions that could then give rise to somatic embryos. The establishment of auxin gradients was correlated with the induced WUS expression. Moreover, the auxin gradients appear to activate PIN1 polar localization within the embryonic callus. Polarized PIN1 is probably responsible for the observed polar auxin transport and auxin accumulation in the SAM and somatic embryo. Suppression of WUS and PIN1 indicated that both genes are necessary for embryo induction through their regulation of downstream gene expression. Our results reveal that establishment of auxin gradients and PIN1-mediated polar auxin transport are essential for WUS induction and somatic embryogenesis. This study sheds new light on how auxin regulates stem cell formation during somatic embryogenesis.     

SHA1, a novel RING finger protein, functions in shoot apical meristem maintenance in Arabidopsis

Post-embryonic plant growth is dependent on a functional shoot apical meristem (SAM) that provides cells for continuous development of new aerial organs. However, how the SAM is dynamically maintained during vegetative development remains largely unclear. We report here the characterization of a new SAM maintenance mutant, sha1-1 (shoot apical meristem arrest 1-1), that shows a primary SAM-deficient phenotype at the adult stage. The SHA1 gene encodes a novel RING finger protein, and is expressed most intensely in the shoot apex. We show that, in the sha1-1 mutant, the primary SAM develops normally during the juvenile vegetative stage, but cell layer structure becomes disorganized after entering the adult vegetative stage, resulting in a dysfunctional SAM that cannot initiate floral primordia. The sha1-1 SAM terminates completely at the stage when the wild-type begins to bolt, producing adult plants with a primary inflorescence-deficient phenotype. These observations indicate that SHA1, a putative E3 ligase, is required for post-embryonic SAM maintenance by controlling proper cellular organization.     

Geminivirus-based vectors for gene silencing in Arabidopsis

Gene silencing, or RNA interference, is a powerful tool for elucidating gene function in Caenorhabditis elegans and Drosophila melanogaster. The vast genetic, developmental and sequence information available for Arabidopsis thaliana makes this an attractive organism in which to develop reliable gene-silencing tools for the plant world. We have developed a system based on the bipartite geminivirus cabbage leaf curl virus (CbLCV) that allows silencing of endogenous genes singly or in combinations in Arabidopsis. Two vectors were tested: a gene-replacement vector derived from the A component; and an insertion vector derived from the B component. Extensive silencing was produced in new growth from the A component vectors, while only minimal silencing and symptoms were seen in the B component vector. Two endogenous genes were silenced simultaneously from the A component vector and silencing of the genes was maintained throughout new growth. Because the CbLCV vectors are DNA vectors they can be inoculated directly from plasmid DNA. Introduction of these vectors into intact plants bypasses transformation and extends the kinds of silencing studies that can be carried out in Arabidopsis.     

Stem Cell Signalling Networks in Plants

The essential nature of meristematic tissues is addressed with reference to conceptual frameworks that have been developed to explain the behaviour of animal stem cells. Comparisons are made between different types of plant meristems with the objective of highlighting common themes that might illuminate underlying mechanisms. A more in depth comparison of the root and shoot apical meristems is made which suggests a common mechanism for maintaining stem cells. The relevance of organogenesis to stem cell maintenance is discussed, along with the nature of underlying mechanisms which help ensure that stem cell production is balanced with the depletion of cells through differentiation. Mechanisms that integrate stem cell behaviour in the whole plant are considered, with a focus on the roles of auxin and cytokinin. The review concludes with a brief discussion of epigenetic mechanisms that act to stabilise and maintain stem cell populations.     

The Arabidopsis STRESS RESPONSE SUPPRESSOR DEAD‐box RNA helicases are nucleolar‐ and chromocenter‐localized proteins that undergo stress‐mediated relocalization and are involved in epigenetic gene silencing

DEAD‐box RNA helicases are involved in many aspects of RNA metabolism and in diverse biological processes in plants. Arabidopsis thaliana mutants of two DEAD‐box RNA helicases, STRESS RESPONSE SUPPRESSOR1 (STRS1) and STRS2 were previously shown to exhibit tolerance to abiotic stresses and up‐regulated stress‐responsive gene expression. Here, we show that Arabidopsis STRS‐overexpressing lines displayed a less tolerant phenotype and reduced expression of stress‐induced genes confirming the STRSs as attenuators of Arabidopsis stress responses. GFP–STRS fusion proteins exhibited localization to the nucleolus, nucleoplasm and chromocenters and exhibited relocalization in response to abscisic acid (ABA) treatment and various stresses. This relocalization was reversed when stress treatments were removed. The STRS proteins displayed mis‐localization in specific gene‐silencing mutants and exhibited RNA‐dependent ATPase and RNA‐unwinding activities. In particular, STRS2 showed mis‐localization in three out of four mutants of the RNA‐directed DNA methylation (RdDM) pathway while STRS1 was mis‐localized in the hd2c mutant that is defective in histone deacetylase activity. Furthermore, heterochromatic RdDM target loci displayed reduced DNA methylation and increased expression in the strs mutants. Taken together, our findings suggest that the STRS proteins are involved in epigenetic silencing of gene expression to bring about suppression of the Arabidopsis stress response.